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P/NSTL@NTU
Plasmonic Nanophotonics
(電漿奈米光子學)
國立清華大學物理學系2009年3月18日(三)下午14:00~15:00
蔡定平台灣大學物理系
中央研究院應用科學中心國家實驗研究院儀器科技研究中心
P/NSTL@NTU
P/NSTL@NTU
A Short Story on Christmas Eve
Martin Moskovits
California Nanosystems Institute,
University of California, Santa Barbara
mmoskovits@ltsc.ucsb.edu
Richard P. Van Duyne
Northwestern University,
vanduyne@chem.northwestern.edu
P/NSTL@NTU
Contents
What is “Plasmonic Nanophotonics”?
Why “Plasmonic Nanophotonics” is
important?
What is current status and progress of
“Plasmonic Nanophotonics”?
What is the future prospect of
“Plasmonic Nanophotonics” ?
P/NSTL@NTU
Physics and technology of generating and
harnessing light and other forms of radiant energy
whose quantum unit is the photon.
The physics includes light emission, transmission,
deflection, amplification and detection by optical
components and instruments, lasers and other light
sources, fiber optics, electro-optical
instrumentation, related hardware and electronics,
and sophisticated systems.
The range of applications of photonics extends from
energy generation to detection, communications
and information processing.
from: www.photonics.com/dictionary/
Photonics
P/NSTL@NTU
Nanophotonics
Nano light emitter
Nano-photonic circuit
Plasmon wave guide
Nanoparticles
N~1
Near-field optics
NanophotonicsPhotonics
Quantum dot laser
Photonic crystal
Optical waveguide
Microcavity laser
Optical MEMS
Nanoparticles
(N~∞)
Bulky material
Propagating light
Diffraction
Diffraction limit of systems and integrations
Device
Material
Signal
carrier
Optical fiber transmission: 40Tb/s transmission speed.
10,000 10,000 channel switching array
Optical nanofabrication: sub~ 100nm line and space
Optical storage: 1Tb/in2 storage density
Future system
Novel functions and phenomena
Physics
P/NSTL@NTU
Plasmonic Nanophotonics
Photonics
Photonics is the physics and technology of generating, manipulating,
detecting, transferring and storing information using photons (light),
which are particularly in the visible and near infra-red light spectrum.
It is the study or application of electromagnetic energy incorporating
optics, laser technology, electrical engineering, materials science,
and information storage and processing.
Photonics is also known as optoelectronics.
Nanophotonics
The generation, manipulation, detection, transmission and storage of
light (both far-field and near-field) using nano-scale materials.
Plasmonic Nanophotonics
Using plasmonic nanostructures to generate, manipulate, detect,
transfer and store light information in nanometer-scale region via
surface plasmons.
P/NSTL@NTU
Plasmonic Nanophotonics
Photonics
Photonics is the science and technology of generating, manipulating,
detecting, transferring and storing information using photons (light),
which are particularly in the visible and near infra-red light spectrum.
It is the study or application of electromagnetic energy incorporating
optics, laser technology, electrical engineering, materials science,
and information storage and processing.
Photonics is also known as optoelectronics.
Nanophotonics
The generation, manipulation, detection, transmission and storage of
light (both far-field and near-field) using nano-scale materials.
Plasmonic Nanophotonics
Using plasmonic nanostructures to generate, manipulate, detect,
transfer and store light information in nanometer-scale region via
surface plasmons.
P/NSTL@NTU
Contents
What is “Plasmonic Nanophotonics”?
Why “Plasmonic Nanophotonics” is
important?
What is current status and progress of
“Plasmonic Nanophotonics”?
What is the future prospect of
“Plasmonic Nanophotonics” ?
P/NSTL@NTU
Evidence of SPP‟s first observed (unknowingly) more than 100 years ago in
experiments with metallic diffraction gratings. [Wood, Phil. Mag. 4, 396 (1902)]
Not understood until the pioneering work of Ritchie [Phys. Rev. 106, 874
(1957)] and Powell & Swan [Phys. Rev. 118, 640 (1960)] on electron energy
loss spectra in metals.
Plasmonic field enhancement effects began to attract attention in the mid-
1970‟s: Surface-Enhanced Raman Spectroscopy [Fleischmann, Hendra &
McQuillan, Dept. of Chemistry, Southampton, Chem. Phys. Lett. 26, 163,
(1974)].
Resurgence of interest in the last few years due to:
Advances in fabrication technologies (e-beam lithography, focused ion-
beam milling, self-assembly), and their availability.
Advances in characterisation and analysis tools (near-field microscopy,
quantitative EM simulation), and their availability.
Potential applications in fields from data transport and processing to
solar cells, high-res. microscopy, biosensing, metamaterials,……
History of plasmon
P/NSTL@NTU
Plasmon
Plasmon = quantum of the collective excitation of free
electrons in solids. A collective oscillation of a metal‟s
conduction electrons.
Surface plasmon = electron plasma oscillations near a
metal surface.
Polariton = „quasiparticle‟ resulting from the coupling of
EM waves with an electric or magnetic dipole-carrying
excitation.
Surface plasmon polariton = A combined excitation
consisting of a surface plasmon and a photon –
essentially, light waves trapped on the surface of a
conductor.
P/NSTL@NTU
Electron collective motion in metal spheres
P/NSTL@NTU
⊕⊕
⊕⊕ ⊕
⊕
⊕⊕
⊕
⊕
⊕
⊕⊕
.
..
..
.....
.
..
⊕⊕
⊕⊕⊕
⊕
⊕⊕
⊕
⊕
⊕
⊕⊕
.
..
..
...
...
..
⊕⊕
⊕⊕ ⊕
⊕
⊕⊕
⊕
⊕
⊕
⊕⊕
.
..
..
....
..
..
⊕⊕
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⊕
⊕⊕
⊕
⊕
⊕
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.
..
..
....
..
..
Coherent oscillatory motion
Polarization of metal sphere under external electric field:
md
mdR
24 3
0
d mR
Resonant excitation
( Classical electrodynamic calculation,
Mie theory )
Conduction electron acts
like an oscillating dipole
P/NSTL@NTU
From SPs to localized SPs
In addition to surface plasmons on a plane surface, in other geometries, such as metallic particles or voids of different topologies, localized surface plasma excitations can be considered. -- Such surface plasma excitations in bounded geometries
are called localized surface plasmons (LSPs).
or
d
• Infinitely large metal
-- fields of surface plasmon
resonances can propagate
along the metal surfaces.
• Metal particles with nanometer size
-- fields of surface plasmon resonances
are confined at the surface of the
plasmonic nanostructures.
P/NSTL@NTU
The field of plasmonP
ublic
ations w
ith „pla
sm
on*‟
in t
he t
itle
0
200
400
600
800
1000
1200
1400
1600
2001 2002 2003 2004 2005 2006 2007 2008
Rapid growth in research activity in recent years:
P/NSTL@NTU
Plasmonics is an international forum for the publication of peer-
reviewed leading-edge original articles that both advance and
report our knowledge base and practice of the interactions of free-
metal electrons, Plasmons.
Topics covered include notable advances in the theory, Physics,
and applications of surface plasmons in metals, to the rapidly
emerging areas of nanotechnology, bio-photonics, sensing,
biochemistry and medicine. Topics, including the theory, synthesis
and optical properties of noble metal nanostructures, patterned
surfaces or materials, continuous or grated surfaces, devices, or
wires for their multifarious applications are particularly welcome.
Typical applications might include but are not limited to, surface
enhanced spectroscopic properties, such as Raman scattering or
fluorescence, as well developments in techniques such as surface
plasmon resonance and near-field scanning optical microscopy.
New Springer Journal of “Plasmonics”
Editor-in-chiefs: Chris D. Geddes, Joseph R. Lakowicz
Regional Editor of Asia: Motoichi Ohtsu
Plasmonics publishes papers that describe new plasmonic based devices, new synthetic
procedures for the preparation of nanostructures and there optical properties, as well their
applications in analytical sensing. Papers describing new synthetic preparations and theory are
particularly welcome.
P/NSTL@NTU
Conductive nanostructured materials open new avenues for
manipulating light on the nanometer-scale.
Specially designed plasmonic structures that act as “smart” optical
nano-antennas for focusing light on nanometer scale with high
spatial and spectral control of the energy concentration.
Nano-antennas for strong enhancing a number of optical
phenomena, such as the extraordinary optical transmittance, Raman
scattering, nonlinear photoluminescence, Kerr optical nonlinearity,
and many other important optical effects.
Plasmonic nanoantennas open up the feasibility to detect molecules
with unsurpassed sensitivity and perform lithography with
nanometer spatial resolution.
Plasmonic nanostructures can be employed for developing photonic
nano-circuits where photons are controlled in a similar manner as
electrons in conventional electronic circuits.
Can be applied for developing novel left-handed materials with
negative refraction index in the optical spectral range that can
revolutionize the current optics.
Why “Plasmonic Nanophotonics” is important?
P/NSTL@NTU
• Short wavelengths
Properties of Plasmonic structures
• Localization of field
Properties of electromagnetic interactions
Plasmonic resonances
of fields are localized at
the interfaces and hot
spots of plasmonic
nanostructures
Plasmonic
nanostructures
2
E
z
0
Incident light
SPs wave
J. P. Kottmann et. al., Phys. Rev. B 64, 235402 (2001).
K. L. Kelly, et. al., J. Phys. Chem. B 107 668 (2003).
Wavelength of SP is
less than the incident
light => high spatial
resolution => better
control of energy
flow in nano-scale
Dispersion
curve of SPs
Light
line
11
p
xk
metal2()
1 dielectric
Optical frequency () with x-ray
wavelength (lSP very small)
• Enhancement
Field and intensity are
enhanced at hot spots, and
accumulation of enhance
electromagnetic energy
happened at certain spots of
plasmonic nanostructures
P/NSTL@NTU
Fundamental blocks to process light in nanoscale devices
with subwavelength dimensions:
Why nanoscale photonics need plasmonics ?
The optical field of plasmonic resonance are localized and
enhanced, and the efficiencies of optical interactions are increased.
The plasmonic nanostructures can be used as optical
nano-antennas to manipulate light in nanometer scale.
• Efficiency of light-matter interactions of wave-optics decreased for the
structure size down to nanometer scale.
• The diffraction limit resulted from wave behavior of light allows little
possibilities to control and manipulate light in nanometer structures.
Role of SPs resonances in nanophotonics: • Metallic nanostructures which support surface plasmon modes =>
localize light fields to a sub-wavelength volume while enhancing
local field strength by several orders of magnitude.
• The field-localization and short-wavelength properties of SPs waves =>
accumulation of local EM energy at hot spots with very small volume.
P/NSTL@NTU
Contents
What is “Plasmonic Nanophotonics”?
Why “Plasmonic Nanophotonics” is
important?
What is current status and progress of
“Plasmonic Nanophotonics”?
What is the future prospect of
“Plasmonic Nanophotonics” ?
P/NSTL@NTU
Current progress of plasmonic nanophotonics
A. Sensing, detection, imaging and recording A-1. Surface plasmon resonance (SPR) sensing
A-2. Surface enhanced Raman scattering (SERS)
A-3. Single molecule detection
A-4. Surface plasmon cover glass slip
A-5. Plasmonic nano optical recording
B. Nano-photonics integration B-1. Plasmonic waveguide
B-2. Nano focusing
B-3. Metamaterial and nano fabrication
C. Photo-chemistry process C-1. Solar cell
C-2. Photocatalytic Micro-reactor
D. Photo-physics interaction D-1. Energy conversion efficiency of luminescence and fluorescence
D-2. OLED efficiency
P/NSTL@NTU
A-1a. Surface plasmon resonance sensing
Schematic diagram of SPR sensor
http://chem.ch.huji.ac.il/~eugeniik/spr.htm#reviews
Advantages:
• Evanescent field interacts with adsorbed molecules only
• Coupling angle strongly depends on d
• Use of well-established surface chemistry for Au (thiol chemistry)
21
)(dm
dmSP
ck
m: dielectric constant of the metal (Au) film
d: dielectric constant of the material in the flow channel
P/NSTL@NTU
A-1b. Surface plasmon resonance sensing
Plasmonic sensing of biological analytes through nanoholes
Schematic of the 2-D nanohole-array SPP transmission setup.
(Inset: SEM image of a section of the gold nanohole array.)
Au hole array
Transmission spectra for the
ethylene glycol solution series (%):
0, 1.96, 3.85, 5.60, 7.40, 9.10.
Monitoring the resonant wavelength
of a SPP mode at the fluid-metal
overlayer in a transmission setup.
The system presented here has the
potential to detect Con A down to
1.43 g/ml (or 53 nM) and to detect
anti-BSA down to 38 ng/ml (or 271
pM).
G. M. Hwang, L. Pang, E. H. Mullen, and Y. Fainman, IEEE Sensor Journal 8, 2074 (2008).
P/NSTL@NTU
A-2a. Surface enhanced Raman scattering
Use single metal nanoparticle for Raman Spectroscopy SERS
Silver
Particle
Sol-Gel Matrix
Molecules
in Solution
Laser
Raman
Scattering
Adsorbed
Molecules
Advanced Fuel Research, Inc., East Hartford, CT
Shuming Nie and Steven R. Emory, Science 275, 1102 (1997).
R. M. Stockle, Y. D. Suh, V. Deckert, R. Zenobi, Chem. Phys. Lett. 318, 131 (2000).
Tip Enhance Raman
Tip
Circles mark C60 normal modes
Stars mark C60 modes due to charge transfer
with the gold tip.
The crosses mark Raman bands of the C60.
Polarization depend
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A-2b. Raman-enhancing substrates based on silver nanoparticle arrays
H. H. Wang, C. Y. Liu, S. B. Wu, N. W. Liu, C. Y. Peng, T. H. Chan, C. F. Hsu, J. K. Wang, and Y. L. Wang, Adv. Mater. 18, 491 (2006).
S: interparticle spacing;
D: particle diameter;
W: interparticle gap
The process for fabricating
silver-filled porous anodic
alumina substrates
SERS spectrum of Rhodamine 6G (R6G)
solution (R6G concentration: 10–6 M)
Polishing Ag deposition
Anodization Remove AAO wall
Pore opening S W D
Top-view SEM image TEM image of Ag nanoparticles
S: 5± 2 nm; D: 25 nm; W: 5 nm
Histograms of D and W
The Ag/AAO exhibits an ultrahigh
Raman signal enhancement factor
due to the unprecedented narrow
gaps between the Ag nanoparticles.
Top curve:
R6G solution on Ag/AAO substrate
Bottom curve:
R6G solution on a typical SERS
substrate prepared by depositing
~30 nm Ag on Si
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A-2c. Polarization dependence of SERS in gold nanoparticle -nanowire systems
Hong Wei, Feng Hao, Yingzhou Huang, Wenzhong Wang, Peter Nordlander, and Hongxing Xu, Nano Lett. 8, 2497 (2008).
Experimental setup
For the separation between particle and wire of 5 nm, the averaged SERS enhancement
is in the order of 106 for the different shapes of the particles, and the maximum local
SERS enhancement for perpendicular polarization is of the order of 1010.
Measured (squares) and calculated (lines) SERS
intensity as a function of polarization angle θ
1μm
200nm
200nm
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A-3a. SP enhanced single molecule detection
H. Yokota, Ki. Saito, and T. Yanagida, Phys. Rev.
Lett. 80, 4606 (1998).
Single molecule imaging
-- using fluorescence
SP enhanced fluorescence
images of a single kinesin
molecule.
0 sec
1 sec
2 sec
3 sec
2.5 mm
K: kinesin 為一種微管附屬性蛋白質 (趨向正端)
M: microtubule
囊泡就是由dynein 與kinesin 沿著微管作運送(耗ATP);kinesin 可與β-tubulin結合,kinesin 與ATP 結合水解後可與β-tubulin 分開
P/NSTL@NTU
A-3b. SP enhanced single molecule detection
C. Sonnichsen, B. M. Reinhard, J. Liphardt, and A. P. Alivisatos,
Nature Biotechnology. 23, 741 (2005).
A molecular ruler based on plasmon coupling of metallic nanoparticles
Spectra shift upon DNA hybridization
Discrete states are observed in the time dependent spectra
peak position (indicated by horizontal dashed lines).
Color effect on directed assembly
of DNA-functionalized Au and Ag
nanoparticles.
Spectra peak position as function of time after
addition of complementary DNA
Single Ag particles blue color.
Ag particle-pairs blue-green color.
Single Au particles green color.
Au particle-pairs orange color.
(particle sizes ~ 40 nm)
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B-1. Guiding of electromagnetic energy
H. Ditlbacher, A. Hohenau, D. Wagner, U. Kreibig, M. Rogers, F. Hofer, F.
R. Aussenegg, and J. R. Krenn, Phys. Rev. Lett. 95, 257403 (2005).
R. M. Dickson and L. A. Lyon, J. Phys. Chem. B 104, 6095 (2000).
532 nm
820 nm532 nm
820 nmAu
Ag
Excitation
Nanowire
Glass
Immersion oil
Objective lens
Collection
SP propagation along the 18.6 mm
long Ag nanowire.
incident wavelength: 785 nm
excited SP wavelength: 414 nm
SP propagation along 4.7 mm long
Au and Ag nanorod
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B-2. Manipulation of electromagnetic wave
L. Yin, V. K. Vlasko-Vlasov, J. Pearson, J. M. Hiller, J. Hua, U.
Welp, D. E. Brown, and C. W. Kimball, Nano Lett. 5, 1399
(2005).
50-nm Ag film containing 19 200-nm holes ranged
on a quarter circle with a 5-mm radius.
Subwavelength focusing
SPP intensity calculated with the dipolar model
NSOM image taken at 532-nm wavelength
SPP subwavelength focusing and guiding
NSOM image
Field amplitude taken at
100 nm from the hole exit
as a function of the incident
wavelength.
Plasmonic visible nanosource
SEM image of the
nanosource structure.
The dimensions of the
Bragg gratings are
a=165 nm, h=80 nm,
and D=295 nm.
Marianne Consonni, Jérôme Hazart, and Gilles Lérondel,
Appl. Phys. Lett. 94, 051105 (2009).
P/NSTL@NTU
• Metamaterials are artificial nanostructures made of metals or composites that
exhibit behavior which (i) either their component materials do not exhibit (ii) or
is enhanced relative to exhibition in the component materials.
• The permittivity () and permeability (m) of a metamaterial are decided primarily
by the constitutive nano structure of the component materials rather than what
it is made of.
B-3a. Developments of metamaterials
What is metamaterial (異向性材料?/異向性物質?/超穎材料?/超穎物質?) ?
Some examples of metamaterials
Fig.4Fig.4
• metallic split-ring-
resonator (SRR) and
wire arrays
• Array of chiral structures• Array of metallic nanowire
or nano pillar pairs
Au nanowire pairs Au nanopillar pairs
Side view
Resin with chiral structure
Cu SRR structureJun-ichi Kato, et al., Appl. Phys.
Lett. 86, 044102 (2005).V. M. Shalaev, et al., physics/0504091 (2005).
A. N. Grigorenko, et al., Nature 438, 335 (2005).
T. J. Yen, et al., Science 308,
1494 (2004).
P/NSTL@NTU
B-3b. Nano assembly and patterning
R. Jin, Y. C. Cao, E. Hao, G. S. Métraux, G. C. Schatz, and C. A. Mirkinthe, Nature 425, 487 (2003).
W. Srituravanich, N. Fang, C. Sun, Q. Luo, and X. Zhang, Nano Lett. 4, 1085 (2004).
Mask
Optical spectra
of Ag nanoprisms
Optical subwavelength lithography
Theoretical modelling of
the optical spectra of two
different-sized nanoprisms.
-- The calculated plasmon
bands reproduce the
experimentally observed
spectrum.
AFM image of a pattern
obtained by SP lithography.
(using l = 365 nm and a
mask of hole array with
period of 170 nm)
2D hole array on Al
substrate (fabricated by FIB)
Spectrum measurement
of far-field transmission of
hole arrays with different
periods.
TEM image of
Ag nanoprisms
time
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B-3c. Plasmonic Nanolithography
M. Derouard, and J. Hazart et al., Opt. Express 15, 4238 (2007).
Schematic cross-section of a plasmon
interference printing system
The illumination generates counter-propagating
surface plasmons.
The SPs interfere on the central metallic area.
Then, the corresponding field is printed in the
DR1MA/MMA layer.
AFM images
of gratingPrinted patterns
Simulated SPs
inteference fields
Flying plasmonic lens for high-speed
nanolithography
plasmonic flying head
AFM image of arbitrary writing
pattern of „SINAM‟ with 145 nm
linewidth on the TeOx-based
thermal photoresist.
W. Srituravanich, L. Pan, Y. Wang,
C. Sun, D. B. Bogy, and X. Zhang.,
Nat. Nanotechol. 3, 733 (2008).
P/NSTL@NTU
C-1a. SP enhanced photovoltaic conversion efficiency of a solar cell
O. Stenzel, A. Stendal, K. Voigtsberger, C. von Borczyskowski, Sol. Energy Mater.
Sol. Cells 37, 337 (1995).
Solar cell without metal clusters
metal
CuPc
metal/ITO
glass
V
incident
light
metal
CuPc
metal/ITO
glass
V
metal clusters
incident
light
Action spectra
recorded for
different
samples.
Enhancement
b(E) of the
conversion
efficiency as a
function of
photon energy.
Solar cell with metal clusters
Cu
Ag
Au
Cu
Ag
Au
酞菁染料
P/NSTL@NTU
C-1b. Plasmonic enhanced efficiency of photovoltaic organic solar cell
Plasmonic nanocavity arrays for enhanced efficiency in OPV cell
The nanocavity array is formed between a patterned Ag anode and an unpatterned Al cathode.
The power conversion efficiency (ηp) can be increased by a factor of 3.2 relative to an unpatterned device.
Plasmon enhanced performance of organic solar cell
Device structure: Glass substrate/patterned Ag (30nm) /copper phthalocyanine (CuPc)
(20nm)/C60 (40nm)/bathocuproine (BCP) 10nm/Al (50nm)
BCP
CuPc
C60
Simulated field intensity map (λ=838 nm) SEM image of the patterned Ag anodeRatio of patterned to unpatterned device
external quantum efficiency
Schematic diagram of polymer solar cells
based on P3HT: PCBM with Ag nanoparticlesIPCE spectra for two kinds of solar cells
The incident photon to charge
carrier efficiency (ICPE) is
increased ~20% compared to
the reference cell.
(size ~ 20nm)
N. C. Lindquist, W. A. Luhman, S. H. Oh, and R. J. Holmes, Appl. Phys. Lett. 93, 123308 (2008).
S. S. Kim, S. I. Na, J. Jo, D. Y. Kim, and Y. C. Nah, Appl. Phys. Lett. 93, 073307 (2008).
P/NSTL@NTU
C-2. Photocatalytic Micro-reactor
Photoreduction of CO2
CO2 + 2H2O CH3OH + O2
Photoreduction of NOx
NO + NO2 N2 + O2hν
hν
UV light source
Collimated
lens
UV light
guide
Gas inlet
Gas outletOptical fiber
reactor
TiO2 thin
film
Photocatalysis
Optical fiber photo-chemical reactor
Wang et al., Colloids and Surface A. 131, 271 (1998).
Y. Tian and T. Tatsuma, J. Am. Chem. Soc. 127, 7632 (2005).
TiO2
Au
-
+-
+
-
+
hν
catalysis
P/NSTL@NTU
D-1a. SP enhanced energy conversion efficiency of fluorescence and luminescence
T. Nakamura and S. Hayashi, Jap. J. Appl. Phys. 44, 6833 (2005).
SP enhanced fluorescence
Fluorescence spectra of Rose Bengal
with and without 50nm Ag nanoparticles.
Fluorescence enhancement factor for
different sized Ag nanoparticles.
SP enhanced luminescence
PL spectra of
InGaN/GaN QWs
coated with
Ag (red line),
Al (blue line)
and Au (green line).
K. Okamoto, I. Niki, A.
Shvartser, Y.
Narukawa, T. Mukai,
and A. Scherer,
Nature Materials 3,
601 (2004).
P/NSTL@NTUD. Gérard, et al., Phys. Rev. B 77, 045413 (2008). A. Kocabas et al., Opt. Express 16, 12469 (2008).
Nanoaperture-enhanced fluorescence Schematics of the experimental setup.
(Inset: Micrograph of a single nanoaperture
milled in Au film)
D-1b. SP enhanced energy conversion efficiency of fluorescence and luminescence
Fluorescence enhancement factor as a function of the
aperture diameter for Alexa-Fluor 647 dyes at excitation
wavelength λe= 633 nm.
Enhancement factor ηmax ~12 for Au and ηmax~7.7 for Al.
PL enhancement by SPs of a biharmonic metallic grating substrate
(Left) AFM image of biharmonic metallic
surface includes Λ1=500 nm and Λ2=250 nm
gratings.
(Right) PL spectrum of biharmonic metallic
grating coated with silicon rich silicon nitride.
There is 30 times enhancement in PL signal
at wavelengths coinciding with the plasmonic
resonance wavelengths.
P/NSTL@NTU
D-2a. SP enhanced OLED and LED efficiency
J. Feng, T. Okamoto, S. Kawata, Opt. Lett. 30, 2302 (2005).
Enhanced electroluminescence
from the opaque cathode layers
of OLEDs.
Configuration of the corrugated
and flat OLEDs.
flat OLED corrugated OLED
AFM image of
the top metallic
cathode surface
of an OLED
fabricated with
2-D corrugation.
Electroluminesence (EL) spectra
observed at normal directions of
1-D and 2-D corrugated and flat
devices.
Enhanced by a factor of 4
P/NSTL@NTU
D-2b. Plasmonic enhanced LED efficiency
D. M. Yeh, et al., Nanotechnology 19, 345201 (2008).
K. C. Shen, et al., Appl. Phys. Lett. 93, 231111 (2008).
Localized surface plasmon-induced LED emission enhancementSEM images of as-deposited and
thermally annealed nanostructure
Ag thin film of 12 nm in thickness.
EL spectra of a InGaN/GaN QW LED sampleA: LED sample with out Ag
B: LED sample with 12 nm flat Ag film
C: LED sample with 12 nm thermally annealed Ag film
In sample C, the LSP coupling leads to 150% enhancement in peak intensity and 120% enhancement in integrated intensity at the injection current of 20 mA.
The output EL peak intensities of the three LED samples as functions of injection current show that with LSP coupling, sample C can achieve 90-220% output intensity enhancement over the conventional LED (A).
injection current of 20 mA
Metal grating induced LED emission enhancement
EL spectra of a InGaN/GaN QW LED sampleA: LED sample with out Ag
B: LED sample with flat Ag film
C: LED sample with 1D grating Ag film (period and groove depth are 500 and 30 nm)
The total output intensity of an LED of SP-QW coupling can be enhanced by ~200%
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Achievement of current progressSensitivity
Resolution of dielectric difference to a refractive index unit of 510-7 to 510-8
(corresponding to 1-pg/mm2 to 100-fg/mm2)
Single molecular (diameter of 10 to 20 nm) fluorescence detection
Enhancement and Efficiency Near-field enhancement corresponds to SERS locally in excess of 1015
Plasmonic nanostructures can be used to achieve 30 times enhancement in PL
signal or 10 times enhancement in molecule fluorescence.
Surface enhancement Raman and combination with scanning probe microscope
to detect DNA, single nanowire
The light emission efficiency of an LED can be enhanced to 4 to 15 times by using
metal particles or metal grating
Spontaneous emission rate of semiconductor QW (QD) can be 55~100
times faster than normal one
High spatial resolution for imaging, storage and nanolithography The nano recording mark smaller then 100 nm can be readout
A pattern with 90 nm features on a 170 nm period has been obtained by surface
plasmon lithography using an exposure radiation of 365 nm wavelength
Nano-photonics integrated circuit SPs propagate along metal guide with diameter smaller than 50 nm
SPs photonic IC, such as emitter, collector, amplifier, transistor, switch and gate
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Contents
What is “Plasmonic Nanophotonics”?
Why “Plasmonic Nanophotonics” is
important?
What is current status and progress of
“Plasmonic Nanophotonics”?
What is the future prospect of “Plasmonic
Nanophotonics” ?
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Nanophotonics from plasmonic nano structures
Parameters of
plasmonic nano
particles:
Size
Shape
Polarization
Wavelength
Material
Environment
Interactions
between particles
Plasmonic
Nanophotonics:
Nanolithography
Nano sensing
Nano imaging
Nano storage
Nanophotonic
transistor
Integrated nano
photonic devices
etc.
Structures
&
Arrangements
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Basic scheme of optical setup. MLA:
microlens array, L1: lens, DM: dichroic
mirror, OL: objective lens. A is the plane
where multiple focuses are generated
S. Matsuo, S. Juodkazis, H. Misawa,
Appl. Phys. A 80, 683 (2005).
The over view and it
optical microscopic
image
The SEM image of
photopolymetized resin
voxels generated on a
glass substrate
Jun-ichi Kato, N. Takeyasu, Y. Adachi, H. B. Sun, and S.
Kawata, Appl. Phys. Lett. 86, 044102 (2005).
Developments of plasmonic metamaterials
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Metamaterials are macroscopic composites having a manmade,
periodic cellular architecture designed to produce an optimized
combination, not available in nature, of two or more responses
to specific excitation.
A metamaterial is a material which gains its properties from its
structure rather than directly from its composition. To
distinguish metamaterials from other composite materials, the
metamaterial label is usually used for a material which has
unusual properties.
The permittivity (ε) and permeability (μ) of a metamaterial are
decided primarily by the constitutive structure of the component
materials rather than what it is made of.
R.M. Walser, in: W.S. Weiglhofer and A. Lakhtakia (Eds.), “Introduction to
Complex Mediums for Electromagnetics and Optics”, SPIE Press, Bellingham,
WA, USA, 2003. http://en.wikipedia.org/wiki/Metamaterials
Metamaterials
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ε1
1
ε>0,μ>0
Common
Transparent
dielectrics
ε<0,μ>0
Electrical Plasma(Metals at optical
wavelength)
ε>0,μ<0
Magnetic Plasma(Not naturally occurring
at optical wavelength)
ε<0,μ<0
Negative Index
Materials(Not found in nature)
μ
(Evanescent Waves) (Propagating Waves)
(Propagating Waves) (Evanescent Waves)
εand μ diagram
Air
Water
Crystals
Semiconductors
Metals
Natural Optical MaterialsMetamaterials
E,H ~ exp(i(ω/c)nz)
n = ± (ε)1/2 (μ)1/2
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Nanophotonics with Plasmonic/metal optics: A logical next step
From electronics to plasmonic nanophotonics
The operating speed of data transporting and processing systems
The ever-increasing need for faster information processing and
transport is undeniable.
Electronic components are running out of steam due to
issues with RC-delay times.
Photo-detector
Light emitter
Optical
near field
Electric
Optical
amplifiersOptical
near fieldoutput signal
Optical input
terminal
Optical output Optical inputterminalterminal
(control signal)
Optical
switchPhoto-detector
Light emitter
Optical
near field
Electric
Optical
amplifiersOptical
near fieldoutput signal
Optical input
terminal
Optical output Optical inputterminalterminal
(control signal)
Optical
switch
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Integrated Plasmonic nanophotonic device
Single light source
Plasmon waveguide
Photonic Transistor
Wavelength selection
Switching
Input signal light emitter
guiding
Control signal
Switching
Drop & Add
Detector
Output signal
Isolation signal
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Niche of plasmonic nanophotonics
Well developed semiconductor industry
Excellent nano fabrication skill
Interests on new developments
Good support from industry and academy
Blossom and flourish of photonic industry
Two digits growth booming
Strong industrial interests and supports
Demand of upgrade and advancement
Abundance of human resource
Well educated people from many high quality
universities
Experienced and well trained personnel from industry
Rich support from society
Many links to different industrial applications
One for all possibilities and great future
Little investment for tremendous return
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Plasmonic Nanophotonics
Thanks for your
attention…..
Din Ping TsaiDepartment of Physics, National Taiwan University
Research Center for Applied Sciences, Academia Sinica
Instrumentation Technology Research Center,
National Applied Research Laboratories
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